A therapeutic walking trainer with a foot receiving portion for receiving at least a sub-region the forefoot of a user or for forming a connection with a toe of a shoe, having at least one main carrier which can be displaced in and/or counter to an adjustment direction, and with an actively and/or passively operable adjustment unit for the relative adjustment, oriented essentially perpendicular to the adjustment direction, of the foot receiving portion relative to the at least one main carrier.

A portable exercise device includes a first body and a second body. The exercise device also includes a support structure pivotably connecting the first and second bodies. The support structure is configured to move between an engaged position and a disengaged position. The device also includes a resistance mechanism configured to resist movement of the first and second bodies toward one another when the support structure is in the engaged position. When the support structure is in the engaged position, the first body is positioned substantially parallel to the second body such that in a first open, in-use configuration of the device, the first body has a first neutral position relative to a pivot axis and in a second open, in-use configuration of the device, the second body has a second neutral position relative to the pivot axis.

A portable exercise device includes a pedal pivotably connected to a pair of supports. The pedal has a neutral position relative to a pivot axis. The pedal is configured to rotate about the pivot axis in a first direction toward one support and in a second direction, opposite the first direction, toward the other support. The exercise device also includes a resistance mechanism configured to exert a force on the pedal about the pivot axis in a direction opposite to the respective direction of rotation of the pedal about the pivot axis. The device is movable between an open, in-use configuration, where the pedal is disposed in the neutral position to receive a foot of a user and the pair of supports together form a triangular base, and a closed configuration, where the pair of supports are flush against the pedal.

The device is a foot power apparatus which provides a means for therapeutically strengthening the foot using an expansion spring mounted pedal suspended within a support frame assembly. One embodiment of the apparatus comprises which base, which generally resembles the sole of a shoe, and a support frame assembly which is attached at the front end and along the sides of said base. Suspended above the base within the frame assembly by a pair of opposing springs is a pedal transversely positioned to the base. With the user's foot positioned on the base, the front of the foot applies downward pressure to expand the springs while the heel of the foot remains stationary. Removable and interchangeable expansion springs provide customized and more accurate biomechanical motion for the needs of the particular patient. This system allows for the proper flexion biomechanics on an individual basis because of its ability to shorten the foot during the flexion process.

A method is disclosed for using an artificial intelligence engine to interact with a user of an exercise device during an exercise session. The method includes generating, by the artificial intelligence engine, a machine learning model trained to receive data as input, and based on the data, providing an output. While a user performs an exercise using the exercise device, the method includes receiving the data from an input peripheral of a computing device associated with the user. Based on the data being received from the input peripheral, the method includes determining, via the machine learning model, the output to control an aspect of the exercise device.

An exercise device includes a foot support portion pivotably connected to a leg support portion and having a neutral position relative to a pivot axis. The support portion is configured to rotate about the neutral pivot axis in a first direction away from the neutral position and in a second direction away from the neutral position. The second direction is opposite the first direction. The exercise device also includes a resistance mechanism configured to exert a force on the foot support portion about the pivot axis opposite to the respective first and second directions of rotation of the foot support portion about the pivot axis.

A method is disclosed for using an artificial intelligence engine to modify resistance of one or more pedals of an exercise device. The method includes generating, by the artificial intelligence engine, a machine learning model trained to receive one or more measurements as input, and outputting, based on the one or more measurements, a control instruction that causes the exercise device to modify the resistance of the one or more pedals. The method includes receiving the one or more measurements from a sensor associated with the one or more pedals of the exercise device, determining whether the one or more measurements satisfy a trigger condition, and responsive to determining that the one or more measurements satisfy the trigger condition, transmitting the control instruction to the exercise device.

A muscle stretching device comprises a base and a pair of footrests adjustably mounted to the base. The footrests may have an upper surface angled upwardly and a lateral portion height greater than a medial portion height thereof. The footrests may have an upstanding edge rim. The footrests may extend rearwardly from the base. The base may include front and rear fixation pins constructed and arranged to extend upwardly from a top surface of the base. Each footrest may comprise a front fixation opening for connection to a front fixation pin of the base, and a plurality of rear fixation openings for connection to a rear fixation pin of the base. The rear fixation openings may comprise a medial rear fixation opening, an intermediate rear fixation opening and a lateral rear fixation opening. The muscle stretching device may be used for stretching of the user's lower lateral rotation muscles.

A method is disclosed for using an artificial intelligence engine to modify resistance of pedals of an exercise device. The method includes generating, by the artificial intelligence engine, a machine learning model trained to receive measurements as input, and outputting, based on the measurements, a control instruction that causes the exercise device to modify, independently from each other, the resistance of the pedals. While a user performs an exercise using the exercise device, the method includes receiving the measurements from sensors associated with the pedals. The method includes determining, based on the measurements, a quantifiable or qualitative modification to the resistance provided by a pedal of the pedals. The resistance provided by another pedal of the pedals is not modified. The method includes transmitting the control instruction to the exercise device to cause the resistance provided by the pedal to be modified.

The presently disclosed subject matter is directed to a device that can be used to exercise and/or strengthen the muscles of the foot, ankle, and/or leg of a user. The device includes foot-receiving pedal that is sized and shaped to provide support for a user's foot or shoe. The pedal includes a first pair of brackets positioned at the rear of the pedal that allow connection to the support at a joint. The support can include a band that rests against the user's leg to provide comfort during use. The joint allows the pedal to move relative to the support. One or more resistive elements (e.g., springs) attach the support to a second pair of brackets positioned at the front portion of the pedal to provide resistance to the movement of the joint. The support includes an adapter that allows the attachment of the springs to be modified to vary resistance and/or be customized to a user's particular leg shape or length.